Physics:Quantum Scattering matrix: Difference between revisions
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{{Short description|Matrix connecting incoming and outgoing quantum scattering states}} | {{Short description|Matrix connecting incoming and outgoing quantum scattering states}} | ||
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|image=[[File:Quantum_scattering_matrix_yellow.png|430px|Scattering matrix connecting incoming and outgoing quantum states.]] | |image=[[File:Quantum_scattering_matrix_yellow.png|430px|Scattering matrix connecting incoming and outgoing quantum states.]] | ||
|text=The | |text=The scattering matrix is a Book I topic in the Quantum Collection. The S-matrix relates incoming quantum states before an interaction to outgoing states after the interaction, avoiding the need to describe every detail of the intermediate process. Its elements encode transition amplitudes, cross sections, resonances, phase shifts, and conservation laws. The concept is central in particle physics, quantum field theory, nuclear physics, and scattering theory. It connects experimental observables with the abstract structure of unitary time evolution. | ||
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== Incoming and outgoing states == | == Incoming and outgoing states == | ||
In scattering problems, particles or waves begin in a prepared incoming state, interact in a finite region, and are later detected in outgoing channels. The scattering matrix encodes the amplitudes for each allowed transition. | In scattering problems, particles or waves begin in a prepared incoming state, interact in a finite region, and are later detected in outgoing channels. The scattering matrix encodes the amplitudes for each allowed transition. | ||
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== See also == | == See also == | ||
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== References == | == References == | ||
Latest revision as of 23:02, 23 May 2026
The scattering matrix is a Book I topic in the Quantum Collection. The S-matrix relates incoming quantum states before an interaction to outgoing states after the interaction, avoiding the need to describe every detail of the intermediate process. Its elements encode transition amplitudes, cross sections, resonances, phase shifts, and conservation laws. The concept is central in particle physics, quantum field theory, nuclear physics, and scattering theory. It connects experimental observables with the abstract structure of unitary time evolution.
Incoming and outgoing states
In scattering problems, particles or waves begin in a prepared incoming state, interact in a finite region, and are later detected in outgoing channels. The scattering matrix encodes the amplitudes for each allowed transition.
Probabilities are obtained from the squared magnitudes of these amplitudes, while phases encode interference and resonance information.
Role in quantum theory
The scattering matrix is important because many experiments observe particles long before and long after an interaction, not during the interaction itself. Collider events, atomic collisions, and wave scattering can all be organized in this language.
In quantum field theory, the S-matrix is constrained by unitarity, symmetry, causality, and conservation laws. It connects naturally with Feynman diagrams and perturbation theory.
See also
Table of contents (217 articles)
Index
Full contents
References
Source attribution: Physics:Quantum Scattering matrix
